US20090274178A1 - Optical Package Having Deformable Mirrors For Focus Compensation - Google Patents
Optical Package Having Deformable Mirrors For Focus Compensation Download PDFInfo
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- US20090274178A1 US20090274178A1 US12/427,939 US42793909A US2009274178A1 US 20090274178 A1 US20090274178 A1 US 20090274178A1 US 42793909 A US42793909 A US 42793909A US 2009274178 A1 US2009274178 A1 US 2009274178A1
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- adjustable mirror
- optical package
- adjustable
- conversion device
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B26/00—Optical devices or arrangements for the control of light using movable or deformable optical elements
- G02B26/08—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light
- G02B26/0816—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light by means of one or more reflecting elements
- G02B26/0825—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light by means of one or more reflecting elements the reflecting element being a flexible sheet or membrane, e.g. for varying the focus
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B26/00—Optical devices or arrangements for the control of light using movable or deformable optical elements
- G02B26/08—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light
- G02B26/0816—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light by means of one or more reflecting elements
- G02B26/0833—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light by means of one or more reflecting elements the reflecting element being a micromechanical device, e.g. a MEMS mirror, DMD
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- G—PHYSICS
- G02—OPTICS
- G02F—OPTICAL DEVICES OR ARRANGEMENTS FOR THE CONTROL OF LIGHT BY MODIFICATION OF THE OPTICAL PROPERTIES OF THE MEDIA OF THE ELEMENTS INVOLVED THEREIN; NON-LINEAR OPTICS; FREQUENCY-CHANGING OF LIGHT; OPTICAL LOGIC ELEMENTS; OPTICAL ANALOGUE/DIGITAL CONVERTERS
- G02F1/00—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics
- G02F1/35—Non-linear optics
- G02F1/37—Non-linear optics for second-harmonic generation
- G02F1/377—Non-linear optics for second-harmonic generation in an optical waveguide structure
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- G—PHYSICS
- G02—OPTICS
- G02F—OPTICAL DEVICES OR ARRANGEMENTS FOR THE CONTROL OF LIGHT BY MODIFICATION OF THE OPTICAL PROPERTIES OF THE MEDIA OF THE ELEMENTS INVOLVED THEREIN; NON-LINEAR OPTICS; FREQUENCY-CHANGING OF LIGHT; OPTICAL LOGIC ELEMENTS; OPTICAL ANALOGUE/DIGITAL CONVERTERS
- G02F1/00—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics
- G02F1/35—Non-linear optics
- G02F1/3501—Constructional details or arrangements of non-linear optical devices, e.g. shape of non-linear crystals
- G02F1/3503—Structural association of optical elements, e.g. lenses, with the non-linear optical device
Definitions
- the present invention generally relates to semiconductor lasers, laser controllers, optical packages, and other optical systems incorporating semiconductor lasers. More specifically, the present invention relates to the use of deformable mirrors for focus compensation in optical packages that include, inter alia, a semiconductor laser and a second harmonic generation (SHG) crystal or another type of wavelength conversion device.
- optical packages that include, inter alia, a semiconductor laser and a second harmonic generation (SHG) crystal or another type of wavelength conversion device.
- SHG second harmonic generation
- Short wavelength light sources can be formed by combining a single-wavelength semiconductor laser, such as an infrared or near-infrared distributed feedback (DFB) laser, distributed Bragg reflector (DBR) laser, or Fabry-Perot laser, with a light wavelength conversion device, such as a second harmonic generation (SHG) crystal.
- a single-wavelength semiconductor laser such as an infrared or near-infrared distributed feedback (DFB) laser, distributed Bragg reflector (DBR) laser, or Fabry-Perot laser
- DFB distributed feedback
- DBR distributed Bragg reflector
- Fabry-Perot laser Fabry-Perot laser
- the SHG crystal is used to generate higher harmonic waves of the fundamental laser signal.
- the lasing wavelength is preferably tuned to the spectral center of the wavelength converting SHG crystal and the output of the laser is preferably aligned with the waveguide portion at the input facet of the wavelength converting crystal.
- Waveguide optical mode field diameters of typical SHG crystals can be in the range of a few microns.
- PPLN periodically poled lithium niobate
- a micro-opto-electromechanical system MOEMS
- micro-electrical mechanical system MEMS
- similar actuator systems may be operatively coupled to a mirror thereby facilitating tip-tilt adjustment of the mirror.
- MOEMS micro-opto-electromechanical system
- MEMS micro-electrical mechanical system
- Similar actuator systems may be operatively coupled to a mirror thereby facilitating tip-tilt adjustment of the mirror.
- These solutions give excellent results in the lateral dimensions, but do not provide sufficient degrees of freedom to effectuate focusing the beam on the waveguide. While less critical than lateral alignment of the beam with the waveguide, the lack of focus of the beam on the waveguide may significantly decrease the coupling efficiency of the semi-conductor laser with the waveguide. This effect may be more pronounced if the device is exposed to large temperature variations which may further degrade the focus of the beam.
- the precision assembly of the various components in the optical package to a level of a few microns may be required in the axial or focus dimension. Requiring such precision may significantly increase the complexity of the assembly operation and increase the cost of the optical package accordingly.
- an optical package includes a semiconductor laser, an adjustable mirror and a wavelength conversion device comprising a waveguide portion.
- the semiconductor laser, adjustable mirror, and wavelength conversion device are oriented to form an optical pathway between an output of the semiconductor laser and an input of the wavelength conversion device.
- the beam of the semiconductor laser is directed along the optical pathway and onto the adjustable mirror where the beam is reflected by the adjustable mirror onto the waveguide portion of the wavelength conversion device.
- the adjustable mirror may also be either thermally or mechanically deformable such that, when the adjustable mirror is deformed, the path of the beam along the optical pathway is altered thereby focusing the beam on the waveguide portion of the wavelength conversion device.
- the adjustable mirror may also be adjusted such that the beam of the semiconductor laser is positioned on the waveguide portion of the wavelength conversion device.
- FIG. 1 is a schematic illustration of a MEMS mirror-enabled optical alignment package according to one embodiment of the present invention
- FIG. 2 is a schematic illustration of a beam spot of the semiconductor laser positioned on a waveguide portion of the wavelength conversion device
- FIG. 3 depicts the front side of a deformable MEMS mirror according to one embodiment shown and described herein;
- FIG. 4 depicts the textured back side of a deformable MEMS mirror according to one embodiment of the optical package shown and described herein;
- FIG. 5 is a schematic illustration of a deformable MEMS mirror being mechanically deformed about the x-axis according to one embodiment of an optical package shown and described herein;
- FIG. 6 depicts the optical effect of the mechanical deformation of the MEMS mirror of FIGS. 3-5 as shown and described herein;
- FIG. 7 depicts a deformable MEMS mirror comprising a heater according to one embodiment of the optical package shown and described herein;
- FIG. 8 depicts the deformable MEMS mirror of FIG. 7 being thermally deformed about the x-axis according to one embodiment of an optical package shown and described herein;
- FIG. 9 depicts the optical effect of the thermal deformation of the MEMS mirror of FIGS. 7-8 as shown and describe herein.
- FIG. 10 graphically illustrates the improvement in the optical coupling between a semiconductor laser and a wavelength conversion device by applying astigmatic correction through deforming the adjustable MEMS mirror about a single axis;
- FIG. 11 depicts an optical package incorporating an adjustable mirror according to one embodiment shown and described herein.
- FIG. 12 depicts an optical package incorporating an adjustable mirror according to another embodiment shown and described herein.
- FIGS. 1-12 are representative of the positioning and orientation of the various components comprising the optical package shown and described herein. However, it should be understood that FIGS. 1-9 and 11 - 12 are not to scale and that the size and positioning of certain components are exaggerated to better illustrate the interplay between the various components.
- FIG. 1 although the general structure of the various types of optical packages in which the concepts of particular embodiments of the present invention can be incorporated is taught in readily available technical literature relating to the design and fabrication of frequency or wavelength-converted semiconductor laser sources, the concepts of particular embodiments of the present invention may be conveniently illustrated with general reference to an optical package including, for example, a semiconductor laser 110 (labeled “ ⁇ ” in FIG. 1 ) and a wavelength conversion device 120 (labeled “ 2 v ” in FIG. 1 ). In the configuration depicted in FIG.
- the near infrared light emitted by the semiconductor laser 110 is coupled into a waveguide portion of the wavelength conversion device 120 by one or more adjustable mirrors 130 and a suitable lens assembly 135 , which lens assembly 135 may comprise one or more optical elements of unitary or multi-component configuration.
- the optical package illustrated in FIG. 1 is particularly useful in generating a variety of shorter wavelength laser beams from a variety of longer wavelength semiconductor lasers and can be used, for example, as a visible laser source in a laser projection system.
- the adjustable mirror 130 is particularly helpful because it is often difficult to align the output beam emitted by the semiconductor laser 110 with the waveguide portion of the wavelength conversion device 120 .
- waveguide optical mode field diameters of typical SHG crystals such as MgO-doped periodically poled lithium niobate (PPLN) crystals, can be in the range of a few microns.
- PPLN periodically poled lithium niobate
- the lens assembly 135 cooperates with the adjustable mirror 130 to generate a beam spot 115 of comparable size on the input face 122 of the wavelength conversion device 120 .
- the adjustable mirror 130 is configured to introduce beam angular deviation by adjusting a drive mechanism of the adjustable mirror and, as such, can be used to actively align the beam spot 115 with the waveguide portion 124 of the wavelength conversion device 120 by altering the position of the beam spot 115 on the input face 122 of the wavelength conversion device 120 until it is aligned with the waveguide portion 124 of the wavelength conversion device 120 .
- beam alignment may be monitored by providing, for example, a beam splitter 140 and an optical detector 150 in the optical path of the wavelength conversion device 120 .
- the optical detector 150 may be operably connected to a microcontroller or controller 160 (labeled “ ⁇ c” in FIG. 1 ) such that an output signal from the optical detector 150 is received by the controller 160 .
- the controller 160 may be configured to control the position or state of the adjustable mirror 130 by adjusting a drive mechanism of the adjustable mirror and, as such, position the output beam of the semiconductor laser 110 on the input face 122 of the wavelength conversion device 120 .
- the controller 160 may be used to control the position or state of the adjustable mirror 130 as a function of the output signal received from the optical detector 150 .
- the controller 160 may be used to perform an alignment routine such that the beam spot 115 of the semiconductor laser 110 is aligned with the waveguide portion 124 of the wavelength conversion device 120 .
- the adjustable mirror illustrated schematically in FIG. 1 can take a variety of conventional or yet to be developed forms.
- the adjustable mirror is a mirror operatively coupled to a drive mechanism such that the angular orientation of the mirror may be adjusted on 2 axes such that the position of the beam spot 115 may be varied on the input face 122 of the wavelength conversion device 120 .
- the drive mechanism of the adjustable mirror 130 may comprise one or more movable micro-opto-electro-mechanical systems (MOEMS) or micro-electro-mechanical system (MEMS) operatively coupled to a mirror such that the angular orientation of the mirror may be adjusted on at least 2 axes.
- MOEMS micro-opto-electro-mechanical systems
- MEMS micro-electro-mechanical system
- the MEMS or MOEMS devices may be configured and arranged to vary the position of the beam spot 115 on the input face 122 of the wavelength conversion device 120 . Since the mirror is located in the collimated or nearly-collimated beam space of the optical system, adjustment of the mirror angle will result in a change in the x/y position of the beam spot at the input face of the wavelength conversion device.
- Use of MEMS or MOEMS devices enables adjustment of the beam spot position to be done extremely rapidly over large ranges. For example, a MEMS mirror with a ⁇ 1 degree mechanical deflection, when used in conjunction with a 3 mm focal length lens, may allow the beam spot to be angularly displaced ⁇ 100 ⁇ m on the input face of the wavelength conversion device.
- the adjustment of the beam spot may be done at frequencies on the order of 100 Hz to 10 kHz due to the fast response time of the MEMS or MOEMS device.
- the adjustable mirror 130 may comprise one or more liquid lens components configured for beam steering and/or beam focusing. Still further, it is contemplated that the adjustable mirror 130 may comprise one or more mirrors and/or lenses mounted to micro-actuators.
- an adjustable mirror 130 such as a mirror operatively coupled to a MOEMS or MEMS device or other actuator, may facilitate repositioning the mirror about the x and y axes and, therefore, positioning the beam spot on the input face of the wavelength conversion device 120 in the x and y directions
- the adjustable mirror 130 does not allow for adjustment of the focused spot in the z direction, and therefore may not be used to focus or refocus the beam spot on the input face of the wavelength conversion device.
- some MEMS mirror designs do provide mechanisms for positioning the mirror (pure movement of the mirror in the z direction), when the mirror is placed in the collimated or near collimated beam space of the optical package, positioning the mirror in this manner will not result in an appreciable change in the z location of the focused beam spot.
- the adjustable mirror 130 may also be made deformable. For example, as shown in FIG. 9 , if the surface of the adjustable mirror ( 300 in FIG. 9 ) is cylindrically deformed, the focal point of rays reflected by the mirror is altered in the z-direction. Accordingly, by controlling the deformation of the adjustable mirror 130 the beam spot 115 of the semiconductor laser 110 may be focused on the input face of the wavelength conversion device 120 and, more specifically, on the waveguide portion 124 of the wavelength conversion device 120 .
- the lens assembly 135 used in conjunction with the MEMS mirror influences how much mirror distortion is needed to generate a given amount of z axis change in focus.
- a lens assembly 135 is desired because the highly divergent beam of the semiconductor laser must be collimated and refocused into the crystal.
- the numerical apertures of the semiconductor laser and wavelength conversion device are quite large—on the order of 0.15 to 0.3 depending on the axis. In order to capture all of the light emitted from the semiconductor laser requires a high numerical aperture lens assembly, in some cases greater than about 0.3.
- the lens assembly may also have a relatively short focal length so as to minimize overall package size. If the mirror is spherically or cylindrically deformed, then for the optical package shown in FIG. 1 the change in the image position ⁇ z along the z axis may be described by
- ⁇ ⁇ ⁇ z 2 ⁇ f 2 ⁇ ⁇ ⁇ ⁇ R c R c ′ ⁇ R c
- Rc and Rc′ are the initial and final radii of curvature of the mirror
- ⁇ Rc is the change in radius of curvature of the mirror.
- this may be expressed as a change in the peak to valley deformation of the mirror, ⁇ , over the illuminated mirror region, such that
- ⁇ ⁇ ⁇ z - 4 ⁇ f 2 ⁇ ⁇ r 0 2
- the lens assembly may have a focal lengths from about 1 mm to about 5 mm.
- An optical package with such a lens assembly can easily create an amplification of change in focus, ⁇ z, to mirror distortion, ⁇ , on the order of about 20:1.
- the adjustable mirror 130 may be a flexible mirror operatively coupled to a MEMS or MOEMS device.
- the adjustable mirror 130 (now MEMS mirror 200 ) may comprise an outer frame 202 , an inner frame 204 and a mirror portion 206 , as shown in FIG. 3 which depicts the front side 201 of the MEMS mirror 200 .
- a line connecting the inner pivots 212 , 214 defines a singular flexure pivot 207 extending across the mirror portion 206 .
- the singular flexure pivot 207 may be constrained by inner pivots 212 , 214 .
- the singular flexure pivot 207 may also be constrained by the material of the mirror portion 206 .
- the MEMS mirror 200 is substantially symmetric about the pivot axis of the singular flexure pivot 207 such that the singular flexure pivot 207 divides the mirror portion 206 into a first mirror region 230 and a second mirror region 232 .
- the first mirror region 230 of the mirror portion 206 and the second mirror region 232 of the mirror portion may be deformed relative to one another about the pivot axis of the flexure pivot 207 thereby providing deformation of the mirror portion 206 .
- the mirror portion 206 is pivotally attached to the inner frame 204 by inner pivots 212 , 214 .
- the inner frame 204 is pivotally attached to the outer frame 202 by outer pivots 208 , 210 .
- the inner pivots 212 , 214 and outer pivots 208 , 210 may be integral with the mirror portion 206 , the inner frame 204 and the outer frame 202 such as when the MEMS mirror 200 is constructed from a single piece of material.
- the inner pivots 214 , 212 facilitate the rotation of the mirror portion 206 about the x-axis indicated in FIG. 3 while the outer pivots 208 , 210 facilitate the rotation of the mirror portion 206 and the inner frame about the y-axis indicated in FIG. 3 .
- the various embodiments of the adjustable mirror (e.g., the MEMS mirror, MOEMS mirror, etc.) shown in FIGS. 1 , 3 - 9 and 11 - 12 are oriented such that the single axis of deformation of the mirror about which the mirror is deformed is collinear with the x-axis depicted in the figures.
- the adjustable mirror is a MEMS mirror or MOEMS mirror such as the adjustable mirrors depicted in FIGS. 3-9 and 11 - 12
- the singular flexure pivot is collinear with the x-axis depicted in the figures. Accordingly, reference to deformation of the adjustable mirror about a single axis of deformation and/or the singular flexure pivot refers to deformation of the adjustable mirror about the x-axis.
- FIG. 5 shows a cross section of the MEMS mirror 200 of FIG. 3 along the y-axis.
- the MEMS mirror 200 may comprise positioning actuators 226 , 228 which exert a force on the mirror portion 206 at actuator force points 216 , 220 .
- a similar pair of actuators (not shown) may be oriented along the x-axis and configured to exert a force on the inner frame 204 at actuator force points 214 , 218 .
- the positioning actuators 226 , 228 may apply an electrostatic or electromagnetic force to the mirror portion 206 which, when the applied forces are equal and opposite (e.g., the first actuator 226 pushes the mirror portion 206 , the second actuator 228 pulls the mirror portion 206 ) results in a torque applied to the mirror portion 206 which causes the mirror portion 206 to pivot about the x-axis and thereby tilt or rotate out of the x-y plane. Because the forces are equal and opposite, the surface of the mirror remains substantially planar while it is tilted or rotated.
- the positioning actuators 226 , 228 may be utilized to introduce forces that act in the same direction, which, because the mirror is constrained from moving in the z direction by the singular flexure pivot point 207 , will cause the mirror to be deformed about the pivot axis of the singular flexure pivot as the axis of deformation. For example, as shown in FIG.
- the first actuator 226 may be used to apply a force F to the actuator force point 216 of the mirror portion 206 and the second actuator 228 may be used to apply a force f to the actuator force point 220 of the mirror portion 206 , wherein the magnitude of F>f and F and f are in the same direction.
- a torque is also applied to the second mirror region 232 of the mirror portion 206 such that the mirror is forced in a counter-clockwise direction about the x-axis.
- the net torque determined by the magnitude of (F-f), determines the net amount and direction of the mirror rotation. Accordingly, due to the application of forces in the same direction, which create torques in opposing directions about the pivot axis of the singular flexure pivot, the mirror portion 206 is deformed about the x-axis. Because the torques act on the mirror in opposite directions (e.g., clockwise and counter-clockwise) the result is a substantially cylindrical deformation of the MEMS mirror about the x-axis. Further, because the applied forces are unbalanced, the mirror will experience a net torque about the axis of rotation, producing an effective tilt of the mirror about the x-axis.
- the back side 203 of the mirror portion 206 may be textured as shown in FIG. 4 .
- the texturing 221 may comprise grooves or channels scribed into or integrally formed with the back side 203 of the mirror portion 206 .
- the texturing 221 decreases the rigidity of the mirror portion 206 such that, when the MEMS mirror 200 is deformed using unbalanced forces, the deformation results in the mirror portion 206 taking on a substantially cylindrical shape.
- FIG. 6 The optical effects of the cylindrical deformation and simultaneous tilt of the mirror portion 206 of the MEMS mirror 200 are schematically illustrated in FIG. 6 with the solid lines indicating the mirror portion 206 A of the MEMS mirror 200 and associated reflected light prior to deformation and the dashed lines indicating the mirror portion 206 B of the MEMS mirror 200 and associated reflected light after deformation.
- prior to deformation light reflected from the mirror portion 206 A is incident on the waveguide portion 124 of the wavelength conversion device 120 .
- the focal point of this light is actually behind the surface of the wavelength conversion device 120 .
- the cylindrically deformed mirror portion 206 B combined with the tilt of the mirror about the x-axis, increases the convergence angle of light rays between the surface of the deformed mirror portion 206 B and the wavelength conversion device 120 thereby focusing the light at a single point on the input face of the wavelength conversion device 120 .
- the tilt of the cylindrically deformed mirror also results in the beam spot 115 of the focused light being repositioned along the waveguide portion 124 of the wavelength conversion device such that, for example, the beam spot 115 is more concentric with the waveguide portion 124 of the wavelength conversion device 120 .
- the deformation of the mirror portion 206 B is asymmetric with respect to the z-axis, and because the z-axis corresponds to the focal dimension of the mirror portion 206 B, the light rays being focused on the surface of the waveguide portion 124 of the wavelength conversion device 120 is a result of the increased convergence angle caused by the substantially cylindrical deformation.
- FIGS. 3-5 generally show the use of two positioning actuators 226 , 228 positioned on either side of a flexure pivot 207 to facilitate the deformation of the mirror portion 206 of the MEMS mirror 200
- any number of positioning actuators may be used in conjunction with one or more flexure pivots to facilitate the deformation of the adjustable mirror. Accordingly, unless otherwise stated herein, no particular limitation is intended by the recitation of two positioning actuators used in conjunction with a single flexure pivot or the recited arrangement of the positioning actuators and the flexure pivot.
- a MEMS mirror 300 having a similar configuration as the MEMS mirror 200 shown in FIGS. 3 and 4 may comprise a heater 302 , such as a micro heater or resistive heater, disposed on a surface of the mirror portion 306 of the MEMS mirror 300 .
- the heater 302 may be positioned on the back side of the mirror portion 306 .
- the mirror portion 306 is heated, the difference in the coefficient of thermal expansion between the front and back sides of the mirror portion 306 causes the mirror to deform as shown in FIG. 8 depicting a cross section of the MEMS mirror 300 along the y-axis.
- the mirror portion 206 is uniformly heated such that the resulting deformation is substantially cylindrical about a single axis of deformation, specifically the x-axis in the embodiment shown in FIG. 8 .
- the mirror portion 306 may comprise a coating bonded to a surface of the mirror portion 306 .
- the coating (not shown) may have a different coefficient of thermal expansion than the substrate material from which the MEMS mirror 300 is produced.
- the coating may have a relatively greater coefficient of thermal expansion than the substrate material of the MEMS mirror 300 such that the coating may have a relatively large expansion for a given amount of applied thermal energy.
- the coating may be applied to the back side of the mirror portion 306 opposite the mirrored front side of the mirror portion 306 . Because the coating is bonded to and constrained by the mirror portion 306 , the thermal expansion of the coating causes the deformation of the mirror portion 306 as depicted in FIG.
- the applied coating may be selected to achieve a desired amount of deformation of the mirror portion 306 with a corresponding minimal amount of applied thermal energy.
- the coating may include gold, silver, aluminum, or one or more layers of dielectric material optimized for high reflectivity at the operating wavelength of the mirror.
- the deformable mirror may be used in conjunction with a plastic lens assembly, such as a polycarbonate lens assembly, wherein the focal length of the plastic lens assembly is sensitive to temperature variations.
- the focal length of the lens assembly, and therefore the focus of the lens assembly may be adjusted and controlled by controlling the temperature of the plastic lens assembly.
- FIG. 9 The optical effects of the cylindrical deformation of the MEMS mirror 300 about the x-axis are graphically illustrated in FIG. 9 wherein the solid lines indicate the mirror portion 306 A of the MEMS mirror 300 and associated reflected light rays prior to deformation and the dashed lines indicate the mirror portion 306 B of the MEMS mirror 300 and associated reflected light rays after deformation.
- the solid lines indicate the mirror portion 306 A of the MEMS mirror 300 and associated reflected light rays prior to deformation
- the dashed lines indicate the mirror portion 306 B of the MEMS mirror 300 and associated reflected light rays after deformation.
- Prior to deformation light reflected from the mirror has a focal point behind the surface of the wavelength conversion device 120 along the z-axis. As a result, light rays incident on the surface of the waveguide portion 124 of the wavelength conversion device 120 are not focused on a single point.
- light rays reflected by the cylindrically deformed mirror portion 306 B have an increased angle of convergence as a result of the cylindrical shape of the mirror and are, as a result, focused on the surface of the waveguide portion 124 of the wavelength conversion device 120 at a single point.
- the adjustable mirror 130 shown in FIG. 1 may be a deformable MOEMS/MEMS mirror so as to facilitate focus adjustment of a beam of the semiconductor laser 110 onto the wavelength conversion device 120 .
- the adjustable mirror 130 may also comprise a mirror operatively associated with one or more actuators which may be used to position the mirror about the x- and y-axes, as shown in FIG. 1 , such that a beam of the semiconductor laser may be laterally positioned on the input face of the wavelength conversion device.
- the actuators operatively associated with the mirror may be used to apply unbalanced forces and/or unbalanced torques to the mirror such that the mirror may be deformed as described hereinabove.
- the mirror may also comprise one or more heaters positioned on a surface of the mirror to facilitate the application of thermal energy to the mirror and therefore induce a controlled amount of deformation in the mirror.
- the semiconductor laser 110 , the adjustable mirror 130 and the wavelength conversion device 120 may be oriented with respect to one another to define an optical pathway between the output of the semiconductor laser 110 and an input of the wavelength conversion device 120 . More specifically, the semiconductor laser 110 , adjustable mirror 130 , and wavelength conversion device 120 may be configured to form a folded optical pathway as shown in FIG. 1 in which the adjustable mirror 130 is configured to fold the optical path such that the optical path initially passes through the lens assembly 135 to reach the adjustable mirror 130 as a collimated or nearly collimated beam and subsequently returns through the same lens assembly 135 to be focused on the wavelength conversion device 120 .
- This type of optical configuration is particularly applicable to wavelength converted laser sources where the cross-sectional size of the laser beam generated by the semiconductor laser is close to the size of the waveguide on the input face of the wavelength conversion device 120 , in which case a magnification close to one would yield optimum coupling in positioning the beam spot on the input face of the wavelength conversion device 120 .
- reference herein to a “collimated or nearly collimated” beam is intended to cover any beam configuration where the degree of beam divergence or convergence is reduced, directing the beam towards a more collimated state.
- the lens assembly 135 can be described as a dual function, collimating and focusing optical component because it serves to collimate the divergent light output of the laser and refocus the laser light propagating along the optical path of the package into the waveguide portion of the wavelength conversion device.
- This dual function optical component is well suited for applications requiring magnification factors close to one because the lens assembly 135 is used for both collimation and focusing. More specifically, as is illustrated in FIG. 1 , laser light output from the semiconductor laser 110 is, in sequence, refracted at the first face 131 of the lens assembly 135 , refracted at the second face 132 of the lens assembly 135 , and reflected by the adjustable mirror 130 in the direction of the lens assembly 135 .
- the laser light is reflected back in the direction of the lens assembly 135 , it is first refracted at the second face 132 of the lens assembly 135 and subsequently refracted at the first face 131 of the lens assembly 135 , for focusing on the input face of the wavelength conversion device 120 .
- FIG. 1 depicts the optical package as including a lens assembly 135 , it should be understood that, at least in one embodiment, the beam of the semiconductor laser 110 may be reflected by the adjustable mirror 130 and focused on the input face of the wavelength conversion device 120 without the use of the lens assembly 135 .
- the adjustable mirror 130 is placed close enough to the image focal point of the lens assembly 135 to ensure that the principle ray incident on the input face 122 of the wavelength conversion device 120 is approximately parallel to the principle ray at the output of the optical package. It may also be shown that the configuration illustrated in FIG. 1 also presents some advantages in term of aberration. Indeed, when the output face of the semiconductor laser 110 and the input face of the wavelength conversion device 120 are positioned in approximate alignment with the object focal plane of the lens assembly 135 and the output waveguide of the semiconductor laser 110 and the input waveguide of the wavelength conversion device 120 are symmetric with respect to the optical axis of the lens assembly 135 , it is contemplated that anti symmetric field aberrations, such as coma, can be automatically corrected.
- an optical package having an adjustable mirror 130 that may be deformed to alter the optical pathway between the semiconductor laser 110 and the wavelength conversion device 120 such that the beam of the semiconductor laser may be focused on a waveguide portion 124 of the wavelength conversion device 120 .
- the laser beam of semiconductor laser 110 is focused behind the input face of the wavelength conversion device 120 .
- the laser beam incident on the input face of the wavelength conversion device 120 is not focused and, as a result, the output intensity of the wavelength conversion device is diminished.
- the adjustable mirror 130 may comprise a deformable adjustable mirror such as the MEMS mirrors described hereinabove.
- the adjustable mirror 130 shown in FIG. 11 may be a MEMS mirror having a heater attached to the surface of the mirror such that the mirror may be deformed symmetrically about the x-axis.
- the mirror portion 306 of the adjustable mirror 130 is deformed such that the deformation is substantially cylindrical with the radial axis of symmetry of the cylinder being collinear with the z-axis (e.g., perpendicular to the axis about which mirror is deformed).
- the mirror portion 306 of the adjustable mirror 130 is heated thereby deforming the mirror about the x-axis such that the resulting cylindrical shape is symmetric with respect to the z-axis.
- the deformation of the adjustable mirror 130 causes light incident on the mirror to have a greater angle of convergence than light reflected from the non-deformed mirror. Accordingly, because of the increased convergence, the optical pathway of the beam (i.e., the path indicated by the dashed lines) between the semiconductor laser and the wavelength conversion device is altered such that the beam of the semiconductor laser 110 is focused on the input face of the wavelength conversion device.
- the adjustable mirror may be deformed by the application of unbalanced forces and/or unbalanced torques to the mirror, such as when the adjustable mirror 130 is a MEMS mirror capable of being deformed by the application of unbalanced forces and/or unbalanced torques to the mirror by the MEMS actuators.
- the unbalanced forces and/or torques applied to the adjustable mirror 130 may be a result of the application of different amounts of thermally energy to the adjustable mirror causing the non-symmetric or asymmetric deformation of the mirror about an axis of deformations. In the embodiment shown in FIG.
- the application of unbalanced forces and/or torques on the mirror causes the mirror to deform about the x-axis.
- the unbalanced forces and/or torques may also cause the mirror to be tilted about the x-axis.
- the resulting deformation due to the application of unbalanced forces and/or torques results in the deformed adjustable mirror being asymmetric with respect to the focal axis (z-axis).
- the change in curvature of the mirror may be caused exclusively by the application of heat, and the rotation of the mirror may by due to the application of external forces from electromagnetic or electrostatic actuators.
- the deformation of the adjustable mirror 130 causes light incident on the mirror to be reflected with a greater angle of convergence than light reflected from the non-deformed adjustable mirror 130 . Accordingly, because of the increased convergence, the optical pathway of the beam between the semiconductor laser and the wavelength conversion device is altered such that the beam of the semiconductor laser 110 is focused on the input face of the wavelength conversion. Because of the tilt introduced by the applied forces, the focal point of the beam is also shifted over the input face of the wavelength conversion device 120 .
- the non-symmetrical or asymmetrical deformation of the mirror with respect to the z-axis due to the application of unbalanced forces and/or torques or, alternatively, the application of different amounts of thermal energy introduces some astigmatism into the optical pathway between the semiconductor laser and the wavelength conversion device. Accordingly, the light incident on the input face of the wavelength conversion device is not a product of pure focus, but rather a result of improved focus and astigmatism. However, this astigmatism can be used to correct or compensate for other optical aberrations in the optical package.
- the semiconductor laser may be configured and positioned such that the output beam of the semiconductor laser has a major axis of divergence (e.g., the fast axis of the beam) and a minor axis of divergence (e.g., the slow axis of the beam) with the minor axis of divergence parallel to the singular flexure pivot of the MEMS mirror and the major axis of divergence perpendicular to the singular flexure pivot of the MEMS mirror.
- the major axis of divergence is parallel to the y-axis while the minor axis of divergence is parallel to the x-axis.
- the deformable mirror may be positioned such that, when the deformable mirror is both deformed and tilted about the single axis of deformation, in this example the x-axis, the adjustable mirror has a greater effect on light rays of the beam along the major axis of divergence than light rays along the minor axis of divergence.
- the deformed adjustable mirror may reflect and converge light rays having a relatively higher angle of divergence more than light rays having a relatively lower angle of divergence. Referring to FIG. 4 , this may be accomplished, for example, by applying force to points 216 and 220 , while not points 206 and 218 .
- FIG. 10 The relationship of the coupling between the semiconductor laser and the wavelength conversion device is graphically illustrated in FIG. 10 .
- the dashed line is indicative of the coupling when no compensation or correction mirror (e.g., the MEMS mirror is not deformed) is employed while the solid line indicates astigmatic correction of the defocus (e.g., the MEMS mirror is deformed).
- the coupling between the semiconductor laser and the wavelength conversion device of the optical package shown in FIG. 1 may be improved by deforming the MEMS mirror about a single axis (such as the x-axis, as mentioned above) thereby introducing astigmatic focus correction into the optical package.
- the controller 160 may be used to control the shape of the adjustable mirror and, therefore, the focus of the adjustable mirror. As discussed herein, the controller 160 may be utilized to control a position or state of the adjustable mirror 130 and thereby facilitate the lateral alignment of the beam of the semiconductor laser with the waveguide portion of the wavelength conversion device in the x-y plane. The controller 160 may also be configured to control the shape of the adjustable mirror 130 by providing the appropriate signals to the adjustable mirror 130 to cause the deformation of the adjustable mirror 130 .
- the controller 160 may also be used to adjust the force and/or torque applied to the adjustable mirror 130 by each individual positioning actuator thereby facilitating controlled deformation of the mirror through the application of unbalanced forces and/or torques.
- the controller 160 may be configured to control the amount of thermal energy supplied by heaters positioned on the adjustable mirror 130 . More specifically, the controller 160 maybe configured to adjust the current supplied to the heater and, therefore, the amount of thermal energy produced by the heater. By regulating and controlling the thermal energy produced by the heater, the controller 160 also controls the deformation of the adjustable mirror and therefore the focus of the adjustable mirror.
- the controller 160 may also be configured for closed-loop control of the focus of the adjustable mirror. As discussed herein, the controller may be operatively connected to an optical sensor 150 which provides the controller with a signal indicative of the output intensity of the adjustable optical component. Based on this signal, the controller 160 may be configured to adjust both the position of the beam on the input face of the wavelength conversion device and the shape of the adjustable mirror 130 such that the beam is both positioned and focused on the waveguide portion 124 of the wavelength conversion device 120 and the output intensity of the wavelength conversion device 120 is maximized.
- an adjustable and deformable mirror in the optical package described herein facilitates adjusting the focus of the beam of the semiconductor laser on the wavelength conversion device.
- This focus adjustment facilitates the optimization of the output intensity of the optical package throughout the lifetime of the device. For example, should the device be exposed to elevated temperatures, the relative position of components in the optical package may change and, as a result, the semiconductor laser may no longer be focused on the wavelength conversion device.
- the use of the deformable adjustable mirror facilitates refocusing the semiconductor laser on the wavelength conversion device thereby compensating for the thermal effects.
- incorporating focus adjustment in the optical component loosens the tolerances that must be maintained during the manufacture of the device. Accordingly, this reduces the complexity of the manufacturing process and, as such, the overall cost of the optical package.
- the optical package of the present invention may be applicable to color image-forming laser projection systems, laser-based displays such as heads-up displays in automobiles, or any laser application having a wavelength converted output where optical alignment and focus are issues. It is further contemplated that the alignment methods discussed herein will have utility in conjunction with a variety of semiconductor lasers, including but not limited to DBR and DFB lasers, Fabry-Perot lasers, and many types of external cavity lasers.
- references herein of a component being “programmed” in a particular way, “configured” or “programmed” to embody a particular property or function are structural recitations as opposed to recitations of intended use. More specifically, the references herein to the manner in which a component is “programmed” or “configured” denotes an existing physical conditions of the component and, as such, is to be taken as a definite recitation of the structural characteristics of the component.
- references herein to a lens assembly and an adjustable mirror being “configured” to direct a laser beam in a particular manner denotes an existing physical condition of the lens assembly and the adjustable mirror and, as such, is to be taken as a definite recitation of the structural characteristics of the lens assembly and the adjustable mirror.
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Abstract
Description
- The present application claims priority to U.S. Provisional Patent Application Ser. No. 61/049,212, filed on Apr. 30, 2008.
- The present invention generally relates to semiconductor lasers, laser controllers, optical packages, and other optical systems incorporating semiconductor lasers. More specifically, the present invention relates to the use of deformable mirrors for focus compensation in optical packages that include, inter alia, a semiconductor laser and a second harmonic generation (SHG) crystal or another type of wavelength conversion device.
- Short wavelength light sources can be formed by combining a single-wavelength semiconductor laser, such as an infrared or near-infrared distributed feedback (DFB) laser, distributed Bragg reflector (DBR) laser, or Fabry-Perot laser, with a light wavelength conversion device, such as a second harmonic generation (SHG) crystal. Typically, the SHG crystal is used to generate higher harmonic waves of the fundamental laser signal. To do so, the lasing wavelength is preferably tuned to the spectral center of the wavelength converting SHG crystal and the output of the laser is preferably aligned with the waveguide portion at the input facet of the wavelength converting crystal.
- Waveguide optical mode field diameters of typical SHG crystals, such as MgO-doped periodically poled lithium niobate (PPLN) crystals, can be in the range of a few microns. As a result, the present inventors have recognized that it can be very challenging to properly align the beam from the laser diode with the waveguide of the SHG crystal and maintain the alignment over the lifetime of the optical package and over large operational temperature variations. One possible solution to this problem is to use a mirror system capable of tip/tilt adjustment to perform the lateral alignment of the beam with the waveguide of the SHG crystal. For example, a micro-opto-electromechanical system (MOEMS), micro-electrical mechanical system (MEMS) or similar actuator systems may be operatively coupled to a mirror thereby facilitating tip-tilt adjustment of the mirror. These solutions give excellent results in the lateral dimensions, but do not provide sufficient degrees of freedom to effectuate focusing the beam on the waveguide. While less critical than lateral alignment of the beam with the waveguide, the lack of focus of the beam on the waveguide may significantly decrease the coupling efficiency of the semi-conductor laser with the waveguide. This effect may be more pronounced if the device is exposed to large temperature variations which may further degrade the focus of the beam. Moreover, in lieu of a focus actuator, the precision assembly of the various components in the optical package to a level of a few microns may be required in the axial or focus dimension. Requiring such precision may significantly increase the complexity of the assembly operation and increase the cost of the optical package accordingly.
- According to one embodiment, an optical package includes a semiconductor laser, an adjustable mirror and a wavelength conversion device comprising a waveguide portion. The semiconductor laser, adjustable mirror, and wavelength conversion device are oriented to form an optical pathway between an output of the semiconductor laser and an input of the wavelength conversion device. The beam of the semiconductor laser is directed along the optical pathway and onto the adjustable mirror where the beam is reflected by the adjustable mirror onto the waveguide portion of the wavelength conversion device. The adjustable mirror may also be either thermally or mechanically deformable such that, when the adjustable mirror is deformed, the path of the beam along the optical pathway is altered thereby focusing the beam on the waveguide portion of the wavelength conversion device. The adjustable mirror may also be adjusted such that the beam of the semiconductor laser is positioned on the waveguide portion of the wavelength conversion device.
- Additional features and advantages of the invention will be set forth in the detailed description which follows and, in part, will be readily apparent to those skilled in the art from that description or recognized by practicing the invention as described herein, including the detailed description which follows, the claims, as well as the appended drawings. It is to be understood that both the foregoing general description and the following detailed description present embodiments of the invention and are intended to provide an overview or framework for understanding the nature and character of the invention as it is claimed.
- The following detailed description of specific embodiments of the present invention can be best understood when read in conjunction with the following drawings, where like structure is indicated with like reference numerals and in which:
-
FIG. 1 is a schematic illustration of a MEMS mirror-enabled optical alignment package according to one embodiment of the present invention; -
FIG. 2 is a schematic illustration of a beam spot of the semiconductor laser positioned on a waveguide portion of the wavelength conversion device; -
FIG. 3 depicts the front side of a deformable MEMS mirror according to one embodiment shown and described herein; -
FIG. 4 depicts the textured back side of a deformable MEMS mirror according to one embodiment of the optical package shown and described herein; -
FIG. 5 is a schematic illustration of a deformable MEMS mirror being mechanically deformed about the x-axis according to one embodiment of an optical package shown and described herein; -
FIG. 6 depicts the optical effect of the mechanical deformation of the MEMS mirror ofFIGS. 3-5 as shown and described herein; -
FIG. 7 depicts a deformable MEMS mirror comprising a heater according to one embodiment of the optical package shown and described herein; -
FIG. 8 depicts the deformable MEMS mirror ofFIG. 7 being thermally deformed about the x-axis according to one embodiment of an optical package shown and described herein; -
FIG. 9 depicts the optical effect of the thermal deformation of the MEMS mirror ofFIGS. 7-8 as shown and describe herein. -
FIG. 10 graphically illustrates the improvement in the optical coupling between a semiconductor laser and a wavelength conversion device by applying astigmatic correction through deforming the adjustable MEMS mirror about a single axis; -
FIG. 11 depicts an optical package incorporating an adjustable mirror according to one embodiment shown and described herein; and -
FIG. 12 depicts an optical package incorporating an adjustable mirror according to another embodiment shown and described herein. - Accordingly,
FIGS. 1-12 are representative of the positioning and orientation of the various components comprising the optical package shown and described herein. However, it should be understood thatFIGS. 1-9 and 11-12 are not to scale and that the size and positioning of certain components are exaggerated to better illustrate the interplay between the various components. - Referring initially to
FIG. 1 , although the general structure of the various types of optical packages in which the concepts of particular embodiments of the present invention can be incorporated is taught in readily available technical literature relating to the design and fabrication of frequency or wavelength-converted semiconductor laser sources, the concepts of particular embodiments of the present invention may be conveniently illustrated with general reference to an optical package including, for example, a semiconductor laser 110 (labeled “λ” inFIG. 1 ) and a wavelength conversion device 120 (labeled “2 v” inFIG. 1 ). In the configuration depicted inFIG. 1 , the near infrared light emitted by thesemiconductor laser 110 is coupled into a waveguide portion of thewavelength conversion device 120 by one or moreadjustable mirrors 130 and asuitable lens assembly 135, whichlens assembly 135 may comprise one or more optical elements of unitary or multi-component configuration. The optical package illustrated inFIG. 1 is particularly useful in generating a variety of shorter wavelength laser beams from a variety of longer wavelength semiconductor lasers and can be used, for example, as a visible laser source in a laser projection system. - The
adjustable mirror 130 is particularly helpful because it is often difficult to align the output beam emitted by thesemiconductor laser 110 with the waveguide portion of thewavelength conversion device 120. For example, waveguide optical mode field diameters of typical SHG crystals, such as MgO-doped periodically poled lithium niobate (PPLN) crystals, can be in the range of a few microns. Referring toFIGS. 1 and 2 collectively, thelens assembly 135 cooperates with theadjustable mirror 130 to generate abeam spot 115 of comparable size on theinput face 122 of thewavelength conversion device 120. Theadjustable mirror 130 is configured to introduce beam angular deviation by adjusting a drive mechanism of the adjustable mirror and, as such, can be used to actively align thebeam spot 115 with thewaveguide portion 124 of thewavelength conversion device 120 by altering the position of thebeam spot 115 on theinput face 122 of thewavelength conversion device 120 until it is aligned with thewaveguide portion 124 of thewavelength conversion device 120. - In one embodiment, beam alignment may be monitored by providing, for example, a
beam splitter 140 and anoptical detector 150 in the optical path of thewavelength conversion device 120. Theoptical detector 150 may be operably connected to a microcontroller or controller 160 (labeled “μc” inFIG. 1 ) such that an output signal from theoptical detector 150 is received by thecontroller 160. Thecontroller 160 may be configured to control the position or state of theadjustable mirror 130 by adjusting a drive mechanism of the adjustable mirror and, as such, position the output beam of thesemiconductor laser 110 on theinput face 122 of thewavelength conversion device 120. In one embodiment thecontroller 160 may be used to control the position or state of theadjustable mirror 130 as a function of the output signal received from theoptical detector 150. In another embodiment, thecontroller 160 may be used to perform an alignment routine such that thebeam spot 115 of thesemiconductor laser 110 is aligned with thewaveguide portion 124 of thewavelength conversion device 120. - The adjustable mirror illustrated schematically in
FIG. 1 can take a variety of conventional or yet to be developed forms. In one embodiment, it is contemplated that the adjustable mirror is a mirror operatively coupled to a drive mechanism such that the angular orientation of the mirror may be adjusted on 2 axes such that the position of thebeam spot 115 may be varied on theinput face 122 of thewavelength conversion device 120. In another embodiment, it is contemplated that the drive mechanism of theadjustable mirror 130 may comprise one or more movable micro-opto-electro-mechanical systems (MOEMS) or micro-electro-mechanical system (MEMS) operatively coupled to a mirror such that the angular orientation of the mirror may be adjusted on at least 2 axes. The MEMS or MOEMS devices may be configured and arranged to vary the position of thebeam spot 115 on theinput face 122 of thewavelength conversion device 120. Since the mirror is located in the collimated or nearly-collimated beam space of the optical system, adjustment of the mirror angle will result in a change in the x/y position of the beam spot at the input face of the wavelength conversion device. Use of MEMS or MOEMS devices enables adjustment of the beam spot position to be done extremely rapidly over large ranges. For example, a MEMS mirror with a ±1 degree mechanical deflection, when used in conjunction with a 3 mm focal length lens, may allow the beam spot to be angularly displaced ±100 μm on the input face of the wavelength conversion device. The adjustment of the beam spot may be done at frequencies on the order of 100 Hz to 10 kHz due to the fast response time of the MEMS or MOEMS device. Alternatively or additionally, theadjustable mirror 130 may comprise one or more liquid lens components configured for beam steering and/or beam focusing. Still further, it is contemplated that theadjustable mirror 130 may comprise one or more mirrors and/or lenses mounted to micro-actuators. - While an
adjustable mirror 130, such as a mirror operatively coupled to a MOEMS or MEMS device or other actuator, may facilitate repositioning the mirror about the x and y axes and, therefore, positioning the beam spot on the input face of thewavelength conversion device 120 in the x and y directions, theadjustable mirror 130 does not allow for adjustment of the focused spot in the z direction, and therefore may not be used to focus or refocus the beam spot on the input face of the wavelength conversion device. While some MEMS mirror designs do provide mechanisms for positioning the mirror (pure movement of the mirror in the z direction), when the mirror is placed in the collimated or near collimated beam space of the optical package, positioning the mirror in this manner will not result in an appreciable change in the z location of the focused beam spot. Accordingly, in order to facilitate focusing or refocusing thebeam spot 115 on thewavelength conversion device 120, theadjustable mirror 130 may also be made deformable. For example, as shown inFIG. 9 , if the surface of the adjustable mirror (300 inFIG. 9 ) is cylindrically deformed, the focal point of rays reflected by the mirror is altered in the z-direction. Accordingly, by controlling the deformation of theadjustable mirror 130 thebeam spot 115 of thesemiconductor laser 110 may be focused on the input face of thewavelength conversion device 120 and, more specifically, on thewaveguide portion 124 of thewavelength conversion device 120. - The
lens assembly 135 used in conjunction with the MEMS mirror influences how much mirror distortion is needed to generate a given amount of z axis change in focus. Alens assembly 135 is desired because the highly divergent beam of the semiconductor laser must be collimated and refocused into the crystal. The numerical apertures of the semiconductor laser and wavelength conversion device are quite large—on the order of 0.15 to 0.3 depending on the axis. In order to capture all of the light emitted from the semiconductor laser requires a high numerical aperture lens assembly, in some cases greater than about 0.3. The lens assembly may also have a relatively short focal length so as to minimize overall package size. If the mirror is spherically or cylindrically deformed, then for the optical package shown inFIG. 1 the change in the image position δz along the z axis may be described by -
- where f is the focal length of the lens assembly, Rc and Rc′ are the initial and final radii of curvature of the mirror, and δRc is the change in radius of curvature of the mirror. Alternatively, this may be expressed as a change in the peak to valley deformation of the mirror, Δ, over the illuminated mirror region, such that
-
- where r0 is the radius of the semiconductor laser beam at the mirror. This formula shows that the change in focus, δz, observed for an applied mirror deformation, Δ, is directly related to the focal length of the lens used. The resulting change in focus δz is illustrated in
FIG. 6 . Therefore it is advantageous to use a lens assembly have a longer focal length to achieve larger amounts of focus adjustment, as long as the numerical aperture of the lens assembly is kept equal to or greater than the numerical aperture of the semiconductor laser and the wavelength conversion device. However, the focal length should not be too long as this makes it difficult to keep the size of the optical package small as the diameter of the lens assembly would need to increase with increasing focal length if a high numerical aperture is to be maintained. In one embodiment, the lens assembly may have a focal lengths from about 1 mm to about 5 mm. An optical package with such a lens assembly can easily create an amplification of change in focus, δz, to mirror distortion, Δ, on the order of about 20:1. - Referring now to
FIGS. 3-5 , in one embodiment, theadjustable mirror 130 may be a flexible mirror operatively coupled to a MEMS or MOEMS device. The adjustable mirror 130 (now MEMS mirror 200) may comprise anouter frame 202, aninner frame 204 and amirror portion 206, as shown inFIG. 3 which depicts thefront side 201 of theMEMS mirror 200. A line connecting theinner pivots singular flexure pivot 207 extending across themirror portion 206. Thesingular flexure pivot 207 may be constrained byinner pivots singular flexure pivot 207 may also be constrained by the material of themirror portion 206. TheMEMS mirror 200 is substantially symmetric about the pivot axis of thesingular flexure pivot 207 such that thesingular flexure pivot 207 divides themirror portion 206 into afirst mirror region 230 and asecond mirror region 232. Thefirst mirror region 230 of themirror portion 206 and thesecond mirror region 232 of the mirror portion may be deformed relative to one another about the pivot axis of theflexure pivot 207 thereby providing deformation of themirror portion 206. Themirror portion 206 is pivotally attached to theinner frame 204 byinner pivots inner frame 204 is pivotally attached to theouter frame 202 byouter pivots inner pivots outer pivots mirror portion 206, theinner frame 204 and theouter frame 202 such as when theMEMS mirror 200 is constructed from a single piece of material. Theinner pivots mirror portion 206 about the x-axis indicated inFIG. 3 while theouter pivots mirror portion 206 and the inner frame about the y-axis indicated inFIG. 3 . - For ease of reference, the various embodiments of the adjustable mirror (e.g., the MEMS mirror, MOEMS mirror, etc.) shown in
FIGS. 1 , 3-9 and 11-12 are oriented such that the single axis of deformation of the mirror about which the mirror is deformed is collinear with the x-axis depicted in the figures. Further, where the adjustable mirror is a MEMS mirror or MOEMS mirror such as the adjustable mirrors depicted inFIGS. 3-9 and 11-12, the singular flexure pivot is collinear with the x-axis depicted in the figures. Accordingly, reference to deformation of the adjustable mirror about a single axis of deformation and/or the singular flexure pivot refers to deformation of the adjustable mirror about the x-axis. - Referring again to
FIGS. 3-5 ,FIG. 5 shows a cross section of theMEMS mirror 200 ofFIG. 3 along the y-axis. TheMEMS mirror 200 may comprisepositioning actuators mirror portion 206 atactuator force points inner frame 204 atactuator force points positioning actuators mirror portion 206 which, when the applied forces are equal and opposite (e.g., thefirst actuator 226 pushes themirror portion 206, thesecond actuator 228 pulls the mirror portion 206) results in a torque applied to themirror portion 206 which causes themirror portion 206 to pivot about the x-axis and thereby tilt or rotate out of the x-y plane. Because the forces are equal and opposite, the surface of the mirror remains substantially planar while it is tilted or rotated. - However, to facilitate a deformation of the
mirror portion 206 about the x-axis, and thereby adjust the focus of thebeam spot 115 on thewavelength conversion device 120, thepositioning actuators flexure pivot point 207, will cause the mirror to be deformed about the pivot axis of the singular flexure pivot as the axis of deformation. For example, as shown inFIG. 4 depicting theback side 203 of theMEMS mirror 200, thefirst actuator 226 may be used to apply a force F to theactuator force point 216 of themirror portion 206 and thesecond actuator 228 may be used to apply a force f to theactuator force point 220 of themirror portion 206, wherein the magnitude of F>f and F and f are in the same direction. This results in a torque applied at thefirst mirror region 230 of themirror portion 206 such that the mirror is forced in a clockwise direction about the x-axis. A torque is also applied to thesecond mirror region 232 of themirror portion 206 such that the mirror is forced in a counter-clockwise direction about the x-axis. The net torque, determined by the magnitude of (F-f), determines the net amount and direction of the mirror rotation. Accordingly, due to the application of forces in the same direction, which create torques in opposing directions about the pivot axis of the singular flexure pivot, themirror portion 206 is deformed about the x-axis. Because the torques act on the mirror in opposite directions (e.g., clockwise and counter-clockwise) the result is a substantially cylindrical deformation of the MEMS mirror about the x-axis. Further, because the applied forces are unbalanced, the mirror will experience a net torque about the axis of rotation, producing an effective tilt of the mirror about the x-axis. - To facilitate the substantially cylindrical deformation of the
MEMS mirror 200, theback side 203 of themirror portion 206 may be textured as shown inFIG. 4 . Thetexturing 221 may comprise grooves or channels scribed into or integrally formed with theback side 203 of themirror portion 206. Thetexturing 221 decreases the rigidity of themirror portion 206 such that, when theMEMS mirror 200 is deformed using unbalanced forces, the deformation results in themirror portion 206 taking on a substantially cylindrical shape. - The optical effects of the cylindrical deformation and simultaneous tilt of the
mirror portion 206 of theMEMS mirror 200 are schematically illustrated inFIG. 6 with the solid lines indicating themirror portion 206A of theMEMS mirror 200 and associated reflected light prior to deformation and the dashed lines indicating themirror portion 206B of theMEMS mirror 200 and associated reflected light after deformation. As shown inFIG. 6 , prior to deformation light reflected from themirror portion 206A is incident on thewaveguide portion 124 of thewavelength conversion device 120. However, the focal point of this light is actually behind the surface of thewavelength conversion device 120. - The cylindrically
deformed mirror portion 206B, combined with the tilt of the mirror about the x-axis, increases the convergence angle of light rays between the surface of thedeformed mirror portion 206B and thewavelength conversion device 120 thereby focusing the light at a single point on the input face of thewavelength conversion device 120. Further, the tilt of the cylindrically deformed mirror also results in thebeam spot 115 of the focused light being repositioned along thewaveguide portion 124 of the wavelength conversion device such that, for example, thebeam spot 115 is more concentric with thewaveguide portion 124 of thewavelength conversion device 120. - Further, because the deformation of the
mirror portion 206B is asymmetric with respect to the z-axis, and because the z-axis corresponds to the focal dimension of themirror portion 206B, the light rays being focused on the surface of thewaveguide portion 124 of thewavelength conversion device 120 is a result of the increased convergence angle caused by the substantially cylindrical deformation. - While the embodiments of the
MEMS mirror 200 shown inFIGS. 3-5 generally show the use of twopositioning actuators flexure pivot 207 to facilitate the deformation of themirror portion 206 of theMEMS mirror 200, it should be understood that any number of positioning actuators may be used in conjunction with one or more flexure pivots to facilitate the deformation of the adjustable mirror. Accordingly, unless otherwise stated herein, no particular limitation is intended by the recitation of two positioning actuators used in conjunction with a single flexure pivot or the recited arrangement of the positioning actuators and the flexure pivot. - Referring now to
FIGS. 7-8 , in another embodiment, aMEMS mirror 300 having a similar configuration as theMEMS mirror 200 shown inFIGS. 3 and 4 may comprise aheater 302, such as a micro heater or resistive heater, disposed on a surface of themirror portion 306 of theMEMS mirror 300. For example, in one embodiment, theheater 302 may be positioned on the back side of themirror portion 306. When themirror portion 306 is heated, the difference in the coefficient of thermal expansion between the front and back sides of themirror portion 306 causes the mirror to deform as shown inFIG. 8 depicting a cross section of theMEMS mirror 300 along the y-axis. In one embodiment, themirror portion 206 is uniformly heated such that the resulting deformation is substantially cylindrical about a single axis of deformation, specifically the x-axis in the embodiment shown inFIG. 8 . - To enhance or amplify the effects of thermal deformation, the
mirror portion 306 may comprise a coating bonded to a surface of themirror portion 306. In one embodiment, the coating (not shown) may have a different coefficient of thermal expansion than the substrate material from which theMEMS mirror 300 is produced. In another embodiment, the coating may have a relatively greater coefficient of thermal expansion than the substrate material of theMEMS mirror 300 such that the coating may have a relatively large expansion for a given amount of applied thermal energy. In this embodiment, the coating may be applied to the back side of themirror portion 306 opposite the mirrored front side of themirror portion 306. Because the coating is bonded to and constrained by themirror portion 306, the thermal expansion of the coating causes the deformation of themirror portion 306 as depicted inFIG. 8 . Accordingly, the applied coating may be selected to achieve a desired amount of deformation of themirror portion 306 with a corresponding minimal amount of applied thermal energy. The coating may include gold, silver, aluminum, or one or more layers of dielectric material optimized for high reflectivity at the operating wavelength of the mirror. - In another embodiment, the deformable mirror may be used in conjunction with a plastic lens assembly, such as a polycarbonate lens assembly, wherein the focal length of the plastic lens assembly is sensitive to temperature variations. The focal length of the lens assembly, and therefore the focus of the lens assembly, may be adjusted and controlled by controlling the temperature of the plastic lens assembly.
- The optical effects of the cylindrical deformation of the
MEMS mirror 300 about the x-axis are graphically illustrated inFIG. 9 wherein the solid lines indicate themirror portion 306A of theMEMS mirror 300 and associated reflected light rays prior to deformation and the dashed lines indicate themirror portion 306B of theMEMS mirror 300 and associated reflected light rays after deformation. Prior to deformation, light reflected from the mirror has a focal point behind the surface of thewavelength conversion device 120 along the z-axis. As a result, light rays incident on the surface of thewaveguide portion 124 of thewavelength conversion device 120 are not focused on a single point. However, light rays reflected by the cylindricallydeformed mirror portion 306B have an increased angle of convergence as a result of the cylindrical shape of the mirror and are, as a result, focused on the surface of thewaveguide portion 124 of thewavelength conversion device 120 at a single point. - Accordingly, the
adjustable mirror 130 shown inFIG. 1 may be a deformable MOEMS/MEMS mirror so as to facilitate focus adjustment of a beam of thesemiconductor laser 110 onto thewavelength conversion device 120. Further, while specific reference is made herein to theadjustable mirror 130 being an adjustable MOEMS/MEMS mirror, it should be understood that theadjustable mirror 130 may also comprise a mirror operatively associated with one or more actuators which may be used to position the mirror about the x- and y-axes, as shown inFIG. 1 , such that a beam of the semiconductor laser may be laterally positioned on the input face of the wavelength conversion device. It should also be understood that the actuators operatively associated with the mirror may be used to apply unbalanced forces and/or unbalanced torques to the mirror such that the mirror may be deformed as described hereinabove. Finally, it will also be understood that the mirror may also comprise one or more heaters positioned on a surface of the mirror to facilitate the application of thermal energy to the mirror and therefore induce a controlled amount of deformation in the mirror. - Referring again to
FIG. 1 , it should now be understood that thesemiconductor laser 110, theadjustable mirror 130 and thewavelength conversion device 120 may be oriented with respect to one another to define an optical pathway between the output of thesemiconductor laser 110 and an input of thewavelength conversion device 120. More specifically, thesemiconductor laser 110,adjustable mirror 130, andwavelength conversion device 120 may be configured to form a folded optical pathway as shown inFIG. 1 in which theadjustable mirror 130 is configured to fold the optical path such that the optical path initially passes through thelens assembly 135 to reach theadjustable mirror 130 as a collimated or nearly collimated beam and subsequently returns through thesame lens assembly 135 to be focused on thewavelength conversion device 120. This type of optical configuration is particularly applicable to wavelength converted laser sources where the cross-sectional size of the laser beam generated by the semiconductor laser is close to the size of the waveguide on the input face of thewavelength conversion device 120, in which case a magnification close to one would yield optimum coupling in positioning the beam spot on the input face of thewavelength conversion device 120. For the purposes of defining and describing the present invention, it is noted that reference herein to a “collimated or nearly collimated” beam is intended to cover any beam configuration where the degree of beam divergence or convergence is reduced, directing the beam towards a more collimated state. - The
lens assembly 135 can be described as a dual function, collimating and focusing optical component because it serves to collimate the divergent light output of the laser and refocus the laser light propagating along the optical path of the package into the waveguide portion of the wavelength conversion device. This dual function optical component is well suited for applications requiring magnification factors close to one because thelens assembly 135 is used for both collimation and focusing. More specifically, as is illustrated inFIG. 1 , laser light output from thesemiconductor laser 110 is, in sequence, refracted at thefirst face 131 of thelens assembly 135, refracted at thesecond face 132 of thelens assembly 135, and reflected by theadjustable mirror 130 in the direction of thelens assembly 135. Once the laser light is reflected back in the direction of thelens assembly 135, it is first refracted at thesecond face 132 of thelens assembly 135 and subsequently refracted at thefirst face 131 of thelens assembly 135, for focusing on the input face of thewavelength conversion device 120. - While
FIG. 1 depicts the optical package as including alens assembly 135, it should be understood that, at least in one embodiment, the beam of thesemiconductor laser 110 may be reflected by theadjustable mirror 130 and focused on the input face of thewavelength conversion device 120 without the use of thelens assembly 135. - In particular embodiments of the present invention, the
adjustable mirror 130 is placed close enough to the image focal point of thelens assembly 135 to ensure that the principle ray incident on theinput face 122 of thewavelength conversion device 120 is approximately parallel to the principle ray at the output of the optical package. It may also be shown that the configuration illustrated inFIG. 1 also presents some advantages in term of aberration. Indeed, when the output face of thesemiconductor laser 110 and the input face of thewavelength conversion device 120 are positioned in approximate alignment with the object focal plane of thelens assembly 135 and the output waveguide of thesemiconductor laser 110 and the input waveguide of thewavelength conversion device 120 are symmetric with respect to the optical axis of thelens assembly 135, it is contemplated that anti symmetric field aberrations, such as coma, can be automatically corrected. - Referring now to
FIG. 11 , an optical package is shown having anadjustable mirror 130 that may be deformed to alter the optical pathway between thesemiconductor laser 110 and thewavelength conversion device 120 such that the beam of the semiconductor laser may be focused on awaveguide portion 124 of thewavelength conversion device 120. As shown by the solid lines representing rays of thesemiconductor laser 110 propagating through the optical package inFIG. 11 , when theadjustable mirror 130 is not deformed, the laser beam ofsemiconductor laser 110 is focused behind the input face of thewavelength conversion device 120. As such, the laser beam incident on the input face of thewavelength conversion device 120 is not focused and, as a result, the output intensity of the wavelength conversion device is diminished. - In order to focus the beam of the
semiconductor laser 110 on thewaveguide portion 124 of thewavelength conversion device 120, theadjustable mirror 130 may comprise a deformable adjustable mirror such as the MEMS mirrors described hereinabove. For example, theadjustable mirror 130 shown inFIG. 11 may be a MEMS mirror having a heater attached to the surface of the mirror such that the mirror may be deformed symmetrically about the x-axis. Themirror portion 306 of theadjustable mirror 130 is deformed such that the deformation is substantially cylindrical with the radial axis of symmetry of the cylinder being collinear with the z-axis (e.g., perpendicular to the axis about which mirror is deformed). For example, in the embodiment shown inFIG. 11 , themirror portion 306 of theadjustable mirror 130 is heated thereby deforming the mirror about the x-axis such that the resulting cylindrical shape is symmetric with respect to the z-axis. The deformation of theadjustable mirror 130 causes light incident on the mirror to have a greater angle of convergence than light reflected from the non-deformed mirror. Accordingly, because of the increased convergence, the optical pathway of the beam (i.e., the path indicated by the dashed lines) between the semiconductor laser and the wavelength conversion device is altered such that the beam of thesemiconductor laser 110 is focused on the input face of the wavelength conversion device. - Referring now to
FIG. 12 , in another embodiment, the adjustable mirror may be deformed by the application of unbalanced forces and/or unbalanced torques to the mirror, such as when theadjustable mirror 130 is a MEMS mirror capable of being deformed by the application of unbalanced forces and/or unbalanced torques to the mirror by the MEMS actuators. Alternatively, in another embodiment, the unbalanced forces and/or torques applied to theadjustable mirror 130 may be a result of the application of different amounts of thermally energy to the adjustable mirror causing the non-symmetric or asymmetric deformation of the mirror about an axis of deformations. In the embodiment shown inFIG. 12 , the application of unbalanced forces and/or torques on the mirror causes the mirror to deform about the x-axis. The unbalanced forces and/or torques may also cause the mirror to be tilted about the x-axis. The resulting deformation due to the application of unbalanced forces and/or torques results in the deformed adjustable mirror being asymmetric with respect to the focal axis (z-axis). In another embodiment, the change in curvature of the mirror may be caused exclusively by the application of heat, and the rotation of the mirror may by due to the application of external forces from electromagnetic or electrostatic actuators. The deformation of theadjustable mirror 130 causes light incident on the mirror to be reflected with a greater angle of convergence than light reflected from the non-deformedadjustable mirror 130. Accordingly, because of the increased convergence, the optical pathway of the beam between the semiconductor laser and the wavelength conversion device is altered such that the beam of thesemiconductor laser 110 is focused on the input face of the wavelength conversion. Because of the tilt introduced by the applied forces, the focal point of the beam is also shifted over the input face of thewavelength conversion device 120. - Further, the non-symmetrical or asymmetrical deformation of the mirror with respect to the z-axis due to the application of unbalanced forces and/or torques or, alternatively, the application of different amounts of thermal energy, introduces some astigmatism into the optical pathway between the semiconductor laser and the wavelength conversion device. Accordingly, the light incident on the input face of the wavelength conversion device is not a product of pure focus, but rather a result of improved focus and astigmatism. However, this astigmatism can be used to correct or compensate for other optical aberrations in the optical package. For example, in one embodiment, the semiconductor laser may be configured and positioned such that the output beam of the semiconductor laser has a major axis of divergence (e.g., the fast axis of the beam) and a minor axis of divergence (e.g., the slow axis of the beam) with the minor axis of divergence parallel to the singular flexure pivot of the MEMS mirror and the major axis of divergence perpendicular to the singular flexure pivot of the MEMS mirror. Referring to
FIG. 12 , the major axis of divergence is parallel to the y-axis while the minor axis of divergence is parallel to the x-axis. The deformable mirror may be positioned such that, when the deformable mirror is both deformed and tilted about the single axis of deformation, in this example the x-axis, the adjustable mirror has a greater effect on light rays of the beam along the major axis of divergence than light rays along the minor axis of divergence. For example, the deformed adjustable mirror may reflect and converge light rays having a relatively higher angle of divergence more than light rays having a relatively lower angle of divergence. Referring toFIG. 4 , this may be accomplished, for example, by applying force topoints FIG. 10 . The dashed line is indicative of the coupling when no compensation or correction mirror (e.g., the MEMS mirror is not deformed) is employed while the solid line indicates astigmatic correction of the defocus (e.g., the MEMS mirror is deformed).FIG. 10 indicates that the coupling between the semiconductor laser and the wavelength conversion device of the optical package shown inFIG. 1 may be improved by deforming the MEMS mirror about a single axis (such as the x-axis, as mentioned above) thereby introducing astigmatic focus correction into the optical package. - In another embodiment, the
controller 160 may be used to control the shape of the adjustable mirror and, therefore, the focus of the adjustable mirror. As discussed herein, thecontroller 160 may be utilized to control a position or state of theadjustable mirror 130 and thereby facilitate the lateral alignment of the beam of the semiconductor laser with the waveguide portion of the wavelength conversion device in the x-y plane. Thecontroller 160 may also be configured to control the shape of theadjustable mirror 130 by providing the appropriate signals to theadjustable mirror 130 to cause the deformation of theadjustable mirror 130. For example, in one embodiment, in addition to thecontroller 160 being used to adjust the position of theadjustable mirror 130 via positioning actuators operatively associated with theadjustable mirror 130, thecontroller 160 may also be used to adjust the force and/or torque applied to theadjustable mirror 130 by each individual positioning actuator thereby facilitating controlled deformation of the mirror through the application of unbalanced forces and/or torques. In another embodiment, thecontroller 160 may be configured to control the amount of thermal energy supplied by heaters positioned on theadjustable mirror 130. More specifically, thecontroller 160 maybe configured to adjust the current supplied to the heater and, therefore, the amount of thermal energy produced by the heater. By regulating and controlling the thermal energy produced by the heater, thecontroller 160 also controls the deformation of the adjustable mirror and therefore the focus of the adjustable mirror. - Further, the
controller 160 may also be configured for closed-loop control of the focus of the adjustable mirror. As discussed herein, the controller may be operatively connected to anoptical sensor 150 which provides the controller with a signal indicative of the output intensity of the adjustable optical component. Based on this signal, thecontroller 160 may be configured to adjust both the position of the beam on the input face of the wavelength conversion device and the shape of theadjustable mirror 130 such that the beam is both positioned and focused on thewaveguide portion 124 of thewavelength conversion device 120 and the output intensity of thewavelength conversion device 120 is maximized. - It should now be understood that the use of an adjustable and deformable mirror in the optical package described herein facilitates adjusting the focus of the beam of the semiconductor laser on the wavelength conversion device. This focus adjustment facilitates the optimization of the output intensity of the optical package throughout the lifetime of the device. For example, should the device be exposed to elevated temperatures, the relative position of components in the optical package may change and, as a result, the semiconductor laser may no longer be focused on the wavelength conversion device. However, the use of the deformable adjustable mirror facilitates refocusing the semiconductor laser on the wavelength conversion device thereby compensating for the thermal effects. Further, incorporating focus adjustment in the optical component loosens the tolerances that must be maintained during the manufacture of the device. Accordingly, this reduces the complexity of the manufacturing process and, as such, the overall cost of the optical package.
- It is contemplated that the optical package of the present invention may be applicable to color image-forming laser projection systems, laser-based displays such as heads-up displays in automobiles, or any laser application having a wavelength converted output where optical alignment and focus are issues. It is further contemplated that the alignment methods discussed herein will have utility in conjunction with a variety of semiconductor lasers, including but not limited to DBR and DFB lasers, Fabry-Perot lasers, and many types of external cavity lasers.
- It is to be understood that the preceding detailed description of the invention is intended to provide an overview or framework for understanding the nature and character of the invention as it is claimed. It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit and scope of the invention. Thus, it is intended that the present invention cover the modifications and variations of this invention provided such modifications and variations come within the scope of the appended claims and their equivalents.
- It is noted that terms like “preferably,” “commonly,” and “typically,” if utilized herein, should not be read to limit the scope of the claimed invention or to imply that certain features are critical, essential, or even important to the structure or function of the claimed invention. Rather, these terms are merely intended to highlight alternative or additional features that may or may not be utilized in a particular embodiment of the present invention.
- For purposes of describing and defining the present invention it is noted that the terms “substantially” and “approximately” are utilized herein to represent the inherent degree of uncertainty that may be attributed to any quantitative comparison, value, measurement, or other representation. The terms “substantially” and “approximately” are also utilized herein to represent the degree by which a quantitative representation may vary from a stated reference without resulting in a change in the basic function of the subject matter at issue.
- It is noted that recitations herein of a component being “programmed” in a particular way, “configured” or “programmed” to embody a particular property or function, are structural recitations as opposed to recitations of intended use. More specifically, the references herein to the manner in which a component is “programmed” or “configured” denotes an existing physical conditions of the component and, as such, is to be taken as a definite recitation of the structural characteristics of the component. For example, references herein to a lens assembly and an adjustable mirror being “configured” to direct a laser beam in a particular manner denotes an existing physical condition of the lens assembly and the adjustable mirror and, as such, is to be taken as a definite recitation of the structural characteristics of the lens assembly and the adjustable mirror.
- Having described the invention in detail and by reference to specific embodiments thereof, it will be apparent that modifications and variations are possible without departing from the scope of the invention defined in the appended claims. More specifically, although some aspects of the present invention are identified herein as preferred or particularly advantageous, it is contemplated that the present invention is not necessarily limited to these preferred aspects of the invention.
Claims (20)
Priority Applications (1)
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US12/427,939 US7916769B2 (en) | 2008-04-30 | 2009-04-22 | Optical package having deformable mirrors for focus compensation |
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US4921208P | 2008-04-30 | 2008-04-30 | |
US12/427,939 US7916769B2 (en) | 2008-04-30 | 2009-04-22 | Optical package having deformable mirrors for focus compensation |
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US20090274178A1 true US20090274178A1 (en) | 2009-11-05 |
US7916769B2 US7916769B2 (en) | 2011-03-29 |
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US12/427,939 Expired - Fee Related US7916769B2 (en) | 2008-04-30 | 2009-04-22 | Optical package having deformable mirrors for focus compensation |
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US (1) | US7916769B2 (en) |
TW (1) | TW201008063A (en) |
WO (1) | WO2009134407A1 (en) |
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US20120098819A1 (en) * | 2010-04-20 | 2012-04-26 | Hiroyuki Furuya | Image display device |
US20140268380A1 (en) * | 2013-03-14 | 2014-09-18 | Andrei Szilagyi | Adaptively Correctable Light Weight Mirror |
US20190245319A1 (en) * | 2016-05-26 | 2019-08-08 | Compound Photonics Limited | Solid-state laser system |
US11032455B2 (en) * | 2017-03-08 | 2021-06-08 | Huawei Technologies Co., Ltd. | Flash, flash adjustment method, optical system, and terminal |
US20220206290A1 (en) * | 2020-12-29 | 2022-06-30 | Beijing Voyager Technology Co., Ltd. | Adaptive beam divergence control in lidar |
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US7898750B2 (en) | 2009-02-26 | 2011-03-01 | Corning Incorporated | Folded optical system and a lens for use in the optical system |
WO2010129039A1 (en) * | 2009-05-05 | 2010-11-11 | Tessera Technologies Hungary Kft. | Folded optic, camera system including the same, and associated methods |
EP2784566A1 (en) * | 2013-03-25 | 2014-10-01 | CSEM Centre Suisse d'Electronique et de Microtechnique SA - Recherche et Développement | Steerable MOEMS device comprising a micromirror |
DE102019102511B4 (en) * | 2019-01-31 | 2020-08-20 | Trumpf Laser- Und Systemtechnik Gmbh | Laser system |
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Also Published As
Publication number | Publication date |
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WO2009134407A1 (en) | 2009-11-05 |
US7916769B2 (en) | 2011-03-29 |
TW201008063A (en) | 2010-02-16 |
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